I've been reading about monads in category theory. One definition of monads uses a pair of adjoint functors. A monad is defined by a roundtrip using those functors. Apparently adjunctions are very important in category theory, but I haven't seen any explanation of Haskell monads in terms of adjoint functors. Has anyone given it a thought?

Edit: Just for fun, I'm going to do this right. Original answer preserved below The current adjunction code for categoryextras now is in the adjunctions package: http://hackage.haskell.org/package/adjunctions I'm just going to work through the state monad explicitly and simply. This code uses An adjunction between f (D > C) and g (C > D), written f  g, can be characterized in a number of ways. We'll use the counit/unit (epsilon/eta) description, which gives two natural transformations (morphisms between functors).
Note that the "a" in counit is really the identity functor in C, and the "a" in unit is really the identity functor in D. We can also recover the homset adjunction definition from the counit/unit definition.
In any case, we can now define a Monad from our unit/counit adjunction like so:
Now we can implement the classic adjunction between (a,) and (a >):
And now a type synonym
And if we load this up in ghci, we can confirm that State is precisely our classic state monad. Note that we can take the opposite composition and get the Costate Comonad (aka the store comonad). There are a bunch of other adjunctions we can make into monads in this fashion (such as (Bool,) Pair), but they're sort of strange monads. Unfortunately we can't do the adjunctions that induce Reader and Writer directly in Haskell in a pleasant way. We can do Cont, but as copumpkin describes, that requires an adjunction from an opposite category, so it actually uses a different "form" of the "Adjoint" typeclass that reverses some arrows. That form is also implemented in a different module in the adjunctions package. this material is covered in a different way by Derek Elkins' article in The Monad Reader 13  Calculating Monads with Category Theory: http://www.haskell.org/wikiupload/8/85/TMRIssue13.pdf Also, Hinze's recent Kan Extensions for Program Optimization paper walks through the construction of the list monad from the adjunction between Old answer: Two references. 1) Categoryextras delivers, as as always, with a representation of adjunctions and how monads arise from them. As usual, it's good to think with, but pretty light on documentation: http://hackage.haskell.org/packages/archive/categoryextras/0.53.5/doc/html/ControlFunctorAdjunction.html 2) Cafe also delivers with a promising but brief discussion on the role of adjunction. Some of which may help in interpreting categoryextras: http://www.haskell.org/pipermail/haskellcafe/2007December/036328.html 


Derek Elkins was showing me recently over dinner how the Cont Monad arises from composing the For some Agda code that illustrates and proves this, please see http://hpaste.org/68257. 


I've found a standard constructions of adjunct functors for any monad by EilenbergMoore, but I'm not sure if it adds any insight to the problem. The second category in the construction is a category of Talgebras. A T algebra adds a "product" to the initial category. So how would it work for a list monad? The functor in the list monad consists of a type constructor, e.g., I must say I'm none the wiser. 


If you are interested,here's some thoughts of a nonexpert on the role of monads and adjunctions in programming languages: First of all, there exists for a given monad Even the use of IO monads is non essential, for the current Haskell type system is powerful enough to realize data encapsulation (existential types). This is my answer to your original question, but I'm curious what Haskell experts have to say about this. On the other hand, as we have noted, there's also a 11 correspondence between monads and
adjunctions to (T)algebras. Adjoints, in MacLane's terms, are 'a way
to express equivalences of categories.'
In a typical setting of adjunctions In the case of Hask and the list monad T, the structure which Apparently, this kind of applications is one of the primary motivations of the creators of Category Theory (MacLane, Eilenberg, etc.), namely, to establish natural equivalence of categories, and transfer a wellknown method in one category to another (e.g. homological methods to topological spaces,algebraic methods to programming, etc.). Here, adjoints and monads are indispensable tools to exploit this connection of categories. (Incidentally, the notion of monads (and its dual, comonads) is so general that one can even go so far as to define 'cohomologies' of Haskell types.But I have not given a thought yet.) As for nondetermistic functions you mentioned, I have much less to say...
But note that; if an adjunction Finally,some remarks: The binary tree functor I mentioned in my last posting easily generalizes to arbitrary data type



This is an old thread, but I found the question interesting, so I did some calculations myself. Hopefully Bartosz is still there and might read this.. In fact, the EilenbergMoore construction does give a very clear picture in this case. (I will use CWM notation with Haskell like syntax) Let (Note that By definition, Now, some easy diagram chasing proves that Conversely, any monoid structure In this way ( So, in this case, the category of Talgebras is just the category of monoid structures definable in Haskell, HaskMon. (Please check that the morphisms in Talgebras are actually monoid homomorphisms.) It also characterizes lists as universal objects in HaskMon, just like free products in Grp, polynomial rings in CRng, etc. The adjuction corresponding to the above construction is where
Next, there is another 'Kleisli category' and the corresponding adjunction.
You can check that it is just the category of Haskell types with morphisms Finally,as is illustrated in CWM, the category of Talgebras (resp. Kleisli category) becomes the terminal (resp. initial) object in the category of adjuctions that define the list monad T in a suitable sense. I suggest to do a similar calculations for the binary tree functor 

